Mechanics of the parasternal intercostals during occluded breaths in dogs

The electrical activity and the respiratory changes in length of the third parasternal intercostal muscle were measured during single-breath airway occlusion in 12 anesthetized, spontaneously breathing dogs in the supine posture. During occluded breaths in the intact animal, the parasternal intercostal was electrically active and shortened while pleural pressure fell. In contrast, after section of the third intercostal nerve at the chondrocostal junction and abolition of parasternal electrical activity, the muscle always lengthened. This inspiratory muscle lengthening must be related to the fall in pleural pressure; it was, however, approximately 50% less than the amount of muscle lengthening produced, for the same fall in pleural pressure, by isolated stimulation of the phrenic nerves. These results indicate that 1) the parasternal inspiratory shortening that occurs during occluded breaths in the dog results primarily from the muscle inspiratory contraction per se, and 2) other muscles of the rib cage, however, contribute to this parasternal shortening by acting on the ribs or the sternum. The present studies also demonstrate the important fact that the parasternal inspiratory contraction in the dog is really agonistic in nature.     

Effect of respiratory muscle tension on lung volume.

The chest wall is modeled as a linear system for which the displacements of points on the chest wall are proportional to the forces that act on the chest wall, namely, airway opening pressure and active tension in the respiratory muscles. A standard theorem of mechanics, the Maxwell reciprocity theorem, is invoked to show that the effect of active muscle tension on lung volume, or airway pressure if the airway is closed, is proportional to the change of muscle length in the relaxation maneuver. This relation was tested experimentally. The shortening of the cranial-caudal distance between a rib pair and the sternum was measured during a relaxation maneuver. These data were used to predict the respiratory effect of forces applied to the ribs and sternum. To test this prediction, a cranial force was applied to the rib pair and a caudal force was applied to the sternum, simulating the forces applied by active tension in the parasternal intercostal muscles. The change in airway pressure, with lung volume held constant, was measured. The measured change in airway pressure agreed well with the prediction. In some dogs, nonlinear deviations from the linear prediction occurred at higher loads. The model and the theorem offer the promise that existing data on the configuration of the chest wall during the relaxation maneuver can be used to compute the mechanical advantage of the respiratory muscles.     

Mechanical advantage of sternomastoid and scalene muscles in dogs

Legrand, Alexandre, Vincent Ninane, and André DeTroyer. Mechanical advantage of sternomastoid and scalene muscles in dogs. J. Appl. Physiol. 82(5):1517-1522, 1997.Theoretical studies have led to the predictionthat the maximal effect of a given respiratory muscle on airway openingpressure (Pao) is the product of muscle mass, the maximal active muscletension per unit cross-sectional area, and the fractional change inmuscle length per unit volume increase of the relaxed chest wall. It has previously been shown that the parasternal intercostals behave inagreement with this prediction (A. De Troyer, A. Legrand, and T. A. Wilson. J. Physiol. (Lond.) 495:239-246, 1996; A. Legrand, T. A. Wilson, and A. DeTroyer. J. Appl. Physiol. 80:2097-2101, 1996). In the present study, we have tested theprediction further by measuring the response to passive inflation andthe pressure-generating ability of the sternomastoid and scalenemuscles in eight anesthetized dogs. With 1-liter passive inflation, thesternomastoids and scalenes shortened by 2.03 ± 0.17 and 5.98 ± 0.43%, respectively, of their relaxation length(P < 0.001). During maximalstimulation, the two muscles caused similar falls in Pao. However, thesternomastoids had greater mass such that the change in Pao (Pao)per unit muscle mass was 0.19 ± 0.02 cmH₂O/g for the scalenes and only0.07 ± 0.01 cmH₂O/g forthe sternomastoids (P < 0.001).After extension of the neck, there was a reduction in both the muscleshortening during passive inflation and the fall in Pao duringstimulation. The Pao per unit muscle mass was thus closely relatedto the change in length; the slope of the relationship was 3.1. These observations further support the concept that the fractional changes inlength of the respiratory muscles during passive inflation can be usedto predict their pressure-generating ability.

     

Inspiratory elevation of the ribs in the dog: primary role of the parasternals

To assess the relative contributions of the different groups of inspiratory intercostal muscles to the cranial motion of the ribs in the dog, we have measured the axial displacement of the fourth rib and recorded the electromyograms of the parasternal intercostal, external intercostal, and levator costae in the third interspace in 15 anesthetized animals breathing at rest. In eight animals, the parasternal intercostals were denervated in interspaces 1-5. This procedure caused a marked increase in the amount of external intercostal and levator costae inspiratory activity, and yet the inspiratory cranial motion of the rib was reduced by 55%. On the other hand, the external intercostals in interspaces 1-5 were sectioned in seven animals, and the reduction in the cranial rib motion was only 22%; the amount of parasternal and levator costae activity, however, was unchanged. When the parasternals in these animals were subsequently denervated, the levator costae inspiratory activity increased markedly, but the inspiratory cranial motion of the rib was abolished or reversed into an inspiratory caudal motion. These studies thus confirm that, in the dog breathing at rest, the parasternal intercostals have a larger role than the external intercostals and levator costae in causing the cranial motion of the ribs during inspiration. A quantitative analysis suggests that the parasternal contribution is approximately 80%.     

Epidermal growth factor stimulates phospholipase A2 in vasopressin-treated rat glomerular mesangial cells.

Epidermal growth factor (EGF) enhances vasopressin- and ionophore-A23187-induced prostaglandin production and arachidonate release by rat glomerular mesangial cells in culture. The purpose of the present study was to delineate the phospholipid pathways involved in this effect. In cells labelled with [14C]arachidonate, EGF significantly enhanced the free arachidonate released in response to A23187 or vasopressin without enhancing the production of [14C]arachidonate-labelled diacylglycerol. EGF increased the [14C]arachidonate-labelled phosphatidic acid formed in response to vasopressin, but to a much smaller extent than it increased free arachidonate release. These results indicate that activation of phospholipase C is not sufficient to explain the increase in free arachidonate release observed on addition of EGF. To examine if EGF enhanced phospholipase A2 activity, mesangial cells were labelled with [2-2H]glycerol and [14C]-arachidonate, and the formation of arachidonate-poor lysophospholipids was studied. When combined with vasopressin, EGF significantly enhanced the formation of arachidonate-poor lysophospholipids as compared with vasopressin alone. The fate of exogenously added lysophosphatidylcholine was not altered after stimulation with vasopressin plus EGF, indicating that decreased deacylation or reacylation of the lysophospholipids was not responsible for their accumulation. Taken together, these results indicate that EGF enhances free arachidonate release by activation of phospholipase A2. The signalling mechanism responsible for the change in phospholipase A2 activity is not known, but could conceivably involve phosphorylation of modulating proteins such as lipocortin or G-proteins.     

Genital stimulation facilitates maternal behavior in estrous ewes

Only a small proportion of ewes at estrus have been found to respond maternally to newborn lambs, and this low maternal responsiveness may be partially attributable to the absence of the genital stimulation which occurs at parturition. Therefore, the effect of artificial genital stimulation on maternal behavior of estrous ewes was investigated. Estrus was synchronized in 33 ewes by placement and withdrawal of progestin-saturated vaginal sponges. Estrous ewes were divided into two groups, a control group and a group receiving 5 min of artificial genital stimulation, and observed following presentation of newborn lambs. Significantly more stimulated ewes licked the lamb and emitted low-pitched bleats in a 30-min test. When genital stimulation was subsequently administered to control ewes, more of them also became maternal so that the two groups were no longer significantly different. These results indicate that absence of genital stimulation is one of the factors contributing to the low maternal responsiveness of estrous ewes. They also demonstrate for the first time that artificial genital stimulation is effective in eliciting maternal behavior in nonpregnant ewes even at physiological concentrations of estradiol.     

Role of pleural pressure in the coupling between the intercostal muscles and the ribs.

The inspiratory intercostal muscles elevate the ribs and thereby elicit a fall in pleural pressure (DeltaPpl) when they contract. In the present study, we initially tested the hypothesis that this DeltaPpl does, in turn, oppose the rib elevation. The cranial rib displacement (Xr) produced by selective activation of the parasternal intercostal muscle in the fourth interspace was measured in dogs, first with the rib cage intact and then after DeltaPpl was eliminated by bilateral pneumothorax. For a given parasternal contraction, Xr was greater after pneumothorax; the increase in Xr per unit decrease in DeltaPpl was 0.98+/-0.11 mm/cmH2O. Because this relation was similar to that obtained during isolated diaphragmatic contraction, we subsequently tested the hypothesis that the increase in Xr observed during breathing after diaphragmatic paralysis was, in part, the result of the decrease in DeltaPpl, and the contribution of the difference in DeltaPpl to the difference in Xr was determined by using the relation between Xr and DeltaPpl during passive inflation. With diaphragmatic paralysis, Xr during inspiration increased approximately threefold, and 47+/-8% of this increase was accounted for by the decrease in DeltaPpl. These observations indicate that 1) DeltaPpl is a primary determinant of rib motion during intercostal muscle contraction and 2) the decrease in DeltaPpl and the increase in intercostal muscle activity contribute equally to the increase in inspiratory cranial displacement of the ribs after diaphragm paralysis.     

Dysfunction of the canine respiratory muscle pump in ascites.

Ascites, a complicating feature of many diseases of the liver and peritoneum, commonly causes dyspnea. The mechanism of this symptom, however, is uncertain. In the present study, progressively increasing ascites was induced in anesthetized dogs, and the hypothesis was initially tested that ascites increases the impedance on the diaphragm and, so, adversely affects the lung-expanding action of the muscle. Ascites produced a gradual increase in abdominal elastance and an expansion of the lower rib cage. Concomitantly, the caudal displacement of the diaphragm and the fall in airway opening pressure during isolated stimulation of the phrenic nerves decreased markedly; transdiaphragmatic pressure during phrenic stimulation also decreased. To assess the adaptation to ascites of the respiratory system overall, we subsequently measured the changes in lung volume, the arterial blood gases, and the electromyogram of the parasternal intercostal muscles during spontaneous breathing. Tidal volume and minute ventilation decreased progressively as ascites increased, leading to an increase in arterial PCO2 and parasternal intercostal inspiratory activity. It is concluded that 1) ascites, acting through an increase in abdominal elastance and an expansion of the lower rib cage, impairs the lung-expanding action of the diaphragm; 2) this impairment elicits a compensatory increase in neural drive to the inspiratory muscles, but the compensation is not sufficient to maintain ventilation; and 3) dyspnea in this setting results in part from the dissociation between increased neural drive and decreased ventilation.